Designing the Future

IF 2.3 4区 环境科学与生态学 Q2 ECOLOGY
Doug Tallamy
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Introduction This paper presents selected findings from a two-day ALTC-funded regional forum held in April 2009 at the University of New South Wales, Australia, as part of the ALTC project “Design based curriculum reform within engineering education”. A forum was proposed for the project because of its effectiveness in focusing stakeholders towards the systemic issues necessary to improve design pedagogy throughout the curriculum (Dym, 2005). The forum brought together 40 leading academics from around Australia, 40 industry representatives primarily from within the Sydney basin and 20 senior students, to reconceptualise engineering curricula around a design core. An engineering design approach was used to consider how a curriculum based strongly around engineering design, that is: problem solving, engineering application and practice, might be achieved. While the forum had many aims, on the first day participants engaged in a structured workshop to identify emerging trends and needs, individual and organisational responses to these challenges, and from this, to specify the competencies which graduate engineers require. It is these findings which are the focus of this paper. The current ALTC project builds on the outcomes and recommendation of a previous ALTC project report entitled “Engineers for the Future: addressing the supply and quality of Australian engineering graduates for the 21 century” (King, 2008). This report reveals that whilst progress has been made in addressing the concerns raised in a 1995-96 review of the national engineering education system (IEA, 1996 in King, 2008), there are areas that have not progressed as expected. The areas relevant to this project are: ISBN 1 876346 59 0 © 2009 AAEE 2009 293 • High levels of student attrition • Lower incentives within the system for improving teaching than for developing research • Effect of research appointments over teaching appointments and barriers to promotion • Concerns that the balance of subjects within current engineering curricula are not adequately matched to graduates’ and industry’s current and future needs It is the last of these areas that this forum sought to address synergistically with recommendation 3 of the preceding ALTC project report (King, 2008): “Engineering schools must develop best practice engineering education, promote student learning and deliver intended graduate outcomes. Curriculum will be based on sound pedagogy, embrace concepts of inclusivity and be adaptable to new technologies and inter-disciplinary areas.” The forum focused on the following milestones within this recommendation: • Increasing employer satisfaction with engineering graduates • Increasing graduate satisfaction with educational experiences and transitions to employment • Increasing recognition and empowerment of engineering educators within universities. • Systematic and holistic educational design practices with learning experiences and assessment strategies that focus on delivery of designated graduate outcomes (King, 2008). The first day’s workshop activities were developed in order to converge quickly on a shared understanding of the required graduate competencies, without churning over old ground. Methodology A unique aspect of this forum was the active involvement of a broad cross-section of participants from industry (37%), academia (49%) and students (14%) totalling 80 in all. The participants generated a significant amount of data (286 lines of comments) from three activities. The comments were later transcribed and triangulated with onsite contemporaneous summaries from several researchers and references to the literature. The data was inductively analysed to reveal emerging themes/categories which were subsequently refined by construct validation (Trochim, 2006). The categories were examined from Activity 1 through to Activity 3 with the intention of identifying relationships which might suggest a narrative. That is, were there any obvious implications for curriculum reform emanating from the data? The results were also examined to determine whether the activities were sufficient as a convergent process for connecting future and current needs to competencies. Day 1 session 1 consisted of keynote presentations followed by the three workshop activities. Each activity was introduced by the session convenor, with the focus question on a slide projected onto the screen. Participants were organised into 10 tables of 8, roughly distributed according to the overall demographics of the workshop. Each of the tables had butcher’s paper, whiteboard pens and a scribe nominated by the group. Each activity had approximately 30 minutes discussion and scribing, after which a spokesperson from each table verbally summarised their results to the rest of the forum. At the end of each activity the butcher’s paper was collected. After the forum the comments were transcribed and then classified into categories by a domain expert. Two other researchers then separately classified the responses and agreed on the resulting categories with minor revisions. The classifications of comments within each category were then refined by the domain expert and one researcher; during this process the category descriptions were further refined either by aggregation into a dominant descriptor or through decomposition into complementary descriptors. For example, “need for increased breadth and depth of engineering degrees” was decomposed into (1) Breadth of knowledge base, (2) Depth of learning/authenticity and (3) Changing curriculum to suit the interpreted emphasis/intent of particular comments. The refinement process was cross-checked and correlated by both main researchers. The categories were then tallied to reveal the top six themes, and the process was repeated with Activity 2. For Activity 3, the responses to the required graduate competencies were mapped against the CDIO syllabus (Crawley, 2001) as this 20th Australasian Association for Engineering Education Conference University of Adelaide, 6-9 December 2009 ISBN 1 876346 59 0 © 2009 AAEE 2009 294 taxonomy provides up to 4 levels of increasing specificity, allowing for a more accurate representation of the transcribed comments. The resulting competencies were then tallied to arrive at the top six. Results and Analysis There were a substantial number of categories (24 in total) identified from the transcripts as indicated in Table 1. 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Table 2 Activity 1: emerging trends – top 6 categories In activity 2 the participants were asked: How are you (and your organisation) dealing/coping with the pressures to survive and thrive in this emerging environment? How are engineering educators adapting? How are universities adapting? This question was asked to prompt the participants to reflect (individually or organisationally) on the strengths/strategies and/or weaknesses/gaps that exist in response to the opportunities or threats presented by the external environment. The question was posed in this way in the expectation that gaps in the competencies of employees and future graduates would be identified in the subsequent activity. The top six responses are shown in Table 3. 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Table 4 Activity 3: top 6 graduate capabilities From the resulting analysis it would appear that the questions served to focus the participants’ attention effectively on the three dimensions: emerging trends; organisational responses; and graduate competencies. However, it should be noted that the responses to Activity 2 were framed mo","PeriodicalId":11492,"journal":{"name":"Ecological Restoration","volume":"40 1","pages":"81 - 82"},"PeriodicalIF":2.3000,"publicationDate":"2022-06-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"1","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Ecological Restoration","FirstCategoryId":"93","ListUrlMain":"https://doi.org/10.5040/9781350036109.ch-018","RegionNum":4,"RegionCategory":"环境科学与生态学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q2","JCRName":"ECOLOGY","Score":null,"Total":0}
引用次数: 1

Abstract

While there have been improvements in Australian engineering education since the 1990s, there are still strong concerns that more progress needs to be made, particularly in the areas of developing graduate competencies and in outcomes-based curricula. This paper reports on the findings from a two-day ALTC-funded forum that sought to establish a shared understanding with the 3 stakeholders (students, academics and industry) about how to achieve a design-based engineering curriculum. This paper reports on the findings from the first day’s activities and reveals that there is a shared desire for design and project-based curricula that would encourage the development of the ‘three-dimensional’ graduate: one who has technical, personal and professional and systems-thinking/design-based competence. Introduction This paper presents selected findings from a two-day ALTC-funded regional forum held in April 2009 at the University of New South Wales, Australia, as part of the ALTC project “Design based curriculum reform within engineering education”. A forum was proposed for the project because of its effectiveness in focusing stakeholders towards the systemic issues necessary to improve design pedagogy throughout the curriculum (Dym, 2005). The forum brought together 40 leading academics from around Australia, 40 industry representatives primarily from within the Sydney basin and 20 senior students, to reconceptualise engineering curricula around a design core. An engineering design approach was used to consider how a curriculum based strongly around engineering design, that is: problem solving, engineering application and practice, might be achieved. While the forum had many aims, on the first day participants engaged in a structured workshop to identify emerging trends and needs, individual and organisational responses to these challenges, and from this, to specify the competencies which graduate engineers require. It is these findings which are the focus of this paper. The current ALTC project builds on the outcomes and recommendation of a previous ALTC project report entitled “Engineers for the Future: addressing the supply and quality of Australian engineering graduates for the 21 century” (King, 2008). This report reveals that whilst progress has been made in addressing the concerns raised in a 1995-96 review of the national engineering education system (IEA, 1996 in King, 2008), there are areas that have not progressed as expected. The areas relevant to this project are: ISBN 1 876346 59 0 © 2009 AAEE 2009 293 • High levels of student attrition • Lower incentives within the system for improving teaching than for developing research • Effect of research appointments over teaching appointments and barriers to promotion • Concerns that the balance of subjects within current engineering curricula are not adequately matched to graduates’ and industry’s current and future needs It is the last of these areas that this forum sought to address synergistically with recommendation 3 of the preceding ALTC project report (King, 2008): “Engineering schools must develop best practice engineering education, promote student learning and deliver intended graduate outcomes. Curriculum will be based on sound pedagogy, embrace concepts of inclusivity and be adaptable to new technologies and inter-disciplinary areas.” The forum focused on the following milestones within this recommendation: • Increasing employer satisfaction with engineering graduates • Increasing graduate satisfaction with educational experiences and transitions to employment • Increasing recognition and empowerment of engineering educators within universities. • Systematic and holistic educational design practices with learning experiences and assessment strategies that focus on delivery of designated graduate outcomes (King, 2008). The first day’s workshop activities were developed in order to converge quickly on a shared understanding of the required graduate competencies, without churning over old ground. Methodology A unique aspect of this forum was the active involvement of a broad cross-section of participants from industry (37%), academia (49%) and students (14%) totalling 80 in all. The participants generated a significant amount of data (286 lines of comments) from three activities. The comments were later transcribed and triangulated with onsite contemporaneous summaries from several researchers and references to the literature. The data was inductively analysed to reveal emerging themes/categories which were subsequently refined by construct validation (Trochim, 2006). The categories were examined from Activity 1 through to Activity 3 with the intention of identifying relationships which might suggest a narrative. That is, were there any obvious implications for curriculum reform emanating from the data? The results were also examined to determine whether the activities were sufficient as a convergent process for connecting future and current needs to competencies. Day 1 session 1 consisted of keynote presentations followed by the three workshop activities. Each activity was introduced by the session convenor, with the focus question on a slide projected onto the screen. Participants were organised into 10 tables of 8, roughly distributed according to the overall demographics of the workshop. Each of the tables had butcher’s paper, whiteboard pens and a scribe nominated by the group. Each activity had approximately 30 minutes discussion and scribing, after which a spokesperson from each table verbally summarised their results to the rest of the forum. At the end of each activity the butcher’s paper was collected. After the forum the comments were transcribed and then classified into categories by a domain expert. Two other researchers then separately classified the responses and agreed on the resulting categories with minor revisions. The classifications of comments within each category were then refined by the domain expert and one researcher; during this process the category descriptions were further refined either by aggregation into a dominant descriptor or through decomposition into complementary descriptors. For example, “need for increased breadth and depth of engineering degrees” was decomposed into (1) Breadth of knowledge base, (2) Depth of learning/authenticity and (3) Changing curriculum to suit the interpreted emphasis/intent of particular comments. The refinement process was cross-checked and correlated by both main researchers. The categories were then tallied to reveal the top six themes, and the process was repeated with Activity 2. For Activity 3, the responses to the required graduate competencies were mapped against the CDIO syllabus (Crawley, 2001) as this 20th Australasian Association for Engineering Education Conference University of Adelaide, 6-9 December 2009 ISBN 1 876346 59 0 © 2009 AAEE 2009 294 taxonomy provides up to 4 levels of increasing specificity, allowing for a more accurate representation of the transcribed comments. The resulting competencies were then tallied to arrive at the top six. Results and Analysis There were a substantial number of categories (24 in total) identified from the transcripts as indicated in Table 1. Table 1 Total Identified Categories Social Awareness Public Perception Breadth of Knowledge Base Increased Specialisation Practical Experience Design Environmental Awareness Rapid Changes in Technology Effects of Globalisation Engineering Systems Scale or Scope of Engineering Problems Professionalism Research/Teaching Dilemma Changing Student Demographics Mobility and Transferable Skills/Qualifications Lifelong Learning Depth of Learning/Authenticity Engagement Changing Engineering Definition Changing Engineering Problem Focus Changing Academic Demographics Changing Curriculum Pathways to Engineering Communication Activity 1 asked the participants: What emerging trends in the environment are having an increasing impact on engineers and engineering organisations? The top six emerging trends are shown in Table 2. Table 2 Activity 1: emerging trends – top 6 categories In activity 2 the participants were asked: How are you (and your organisation) dealing/coping with the pressures to survive and thrive in this emerging environment? How are engineering educators adapting? How are universities adapting? This question was asked to prompt the participants to reflect (individually or organisationally) on the strengths/strategies and/or weaknesses/gaps that exist in response to the opportunities or threats presented by the external environment. The question was posed in this way in the expectation that gaps in the competencies of employees and future graduates would be identified in the subsequent activity. The top six responses are shown in Table 3. Table 3 Activity 2: responding to change – top 6 categories % theme 1 29% changing curriculum 2 18% practical experience 3 18% impacts of globalisation % category 1 22% impacts of globalisation 2 21% environmental awareness 3 18% breadth of knowledge base 4 18% engineering systems 5 13% rapid changes in technology 6 13% research/teaching dilemma 20th Australasian Association for Engineering Education Conference University of Adelaide, 6-9 December 2009 ISBN 1 876346 59 0 © 2009 AAEE 2009 295 4 12% research/teaching dilemma 5 12% navigation (pathways to Engineering) 6 11% breadth of knowledge base In the final workshop activity in session 1, participants were asked: What capabilities will employees, and specifically graduate engineers require if they are to effectively contribute to their organisations and communities into the future? Table 4 Activity 3: top 6 graduate capabilities From the resulting analysis it would appear that the questions served to focus the participants’ attention effectively on the three dimensions: emerging trends; organisational responses; and graduate competencies. However, it should be noted that the responses to Activity 2 were framed mo
设计未来
尽管自20世纪90年代以来,澳大利亚的工程教育有所改善,但仍有人强烈担心,需要取得更多进展,特别是在培养研究生能力和基于成果的课程方面。本文报告了由ALTC资助的为期两天的论坛的研究结果,该论坛旨在与三个利益相关者(学生、学者和行业)就如何实现基于设计的工程课程建立共同的理解。本文报告了第一天活动的结果,并揭示了人们对设计和基于项目的课程的共同愿望,这些课程将鼓励“三维”毕业生的发展:一个具有技术、个人、专业和系统思维/设计能力的毕业生。引言本文介绍了2009年4月在澳大利亚新南威尔士大学举行的为期两天的ALTC资助的区域论坛的部分研究结果,该论坛是ALTC项目“工程教育中基于设计的课程改革”的一部分。建议为该项目设立一个论坛,因为它有效地将利益相关者集中在改进整个课程设计教学法所需的系统性问题上(Dym,2005)。该论坛汇集了来自澳大利亚各地的40位顶尖学者、主要来自悉尼盆地的40位行业代表和20名高年级学生,围绕设计核心重新定义工程课程。工程设计方法用于考虑如何实现以工程设计为基础的课程,即:问题解决、工程应用和实践。虽然论坛有很多目标,但在第一天,参与者就参加了一个结构化的研讨会,以确定新出现的趋势和需求,个人和组织对这些挑战的反应,并从中明确研究生工程师所需的能力。正是这些发现是本文的重点。目前的ALTC项目以ALTC上一份题为“面向未来的工程师:解决21世纪澳大利亚工程毕业生的供应和质量问题”的项目报告的成果和建议为基础(King,2008)。本报告显示,尽管在解决1995-96年对国家工程教育系统的审查中提出的关切方面取得了进展(国际能源署,1996年,King,2008年),但仍有一些领域没有取得预期的进展。与该项目相关的领域是:ISBN 1 876346 59 0©2009 AAEE 2009 293•学生流失率高•系统内改善教学的动机低于发展研究的动机•研究任命对教学任命的影响和晋升障碍•对当前工程课程中科目平衡不充分的担忧与毕业生和行业当前和未来的需求相匹配这是本论坛试图与之前ALTC项目报告(King,2008)的建议3协同解决的最后一个领域:“工程学校必须发展最佳实践工程教育,促进学生学习,并提供预期的研究生成果。课程将以健全的教育学为基础,包含包容性的概念,并适应新技术和跨学科领域。“论坛重点讨论了本建议中的以下里程碑:•提高雇主对工程毕业生的满意度•提高毕业生对教育经历和就业过渡的满意度•增加大学内工程教育工作者的认可和授权。•系统和全面的教育设计实践,包括学习经验和评估策略,重点是交付指定的研究生成果(King,2008)。第一天的研讨会活动是为了在不翻旧账的情况下,迅速达成对所需毕业生能力的共同理解。方法本次论坛的一个独特方面是来自工业界(37%)、学术界(49%)和学生(14%)的广泛参与者的积极参与,总共80人。参与者从三项活动中生成了大量数据(286行评论)。这些评论后来被转录下来,并与几位研究人员的现场同期摘要和文献参考进行了三角化。对数据进行归纳分析,以揭示新出现的主题/类别,这些主题/类别随后通过结构验证进行了提炼(Trochim,2006)。从活动1到活动3对这些类别进行了检查,目的是确定可能暗示叙述的关系。 也就是说,这些数据对课程改革是否有任何明显的影响?还对结果进行了审查,以确定这些活动是否足以作为一个将未来和当前需求与能力联系起来的趋同过程。第一天的第一次会议包括主题演讲,随后是三次讲习班活动。每项活动都由会议召集人介绍,重点问题放在屏幕上的幻灯片上。参与者被分为10张表,每组8人,大致根据研讨会的总体人口统计进行分配。每张桌子上都有肉铺纸、白板笔和小组指定的一名抄写员。每项活动都有大约30分钟的讨论和记录,之后每张桌子上的发言人向论坛的其他人口头总结了他们的结果。每次活动结束时,屠夫的纸都会被收集起来。论坛结束后,评论被转录,然后由领域专家分类。然后,另外两名研究人员分别对回答进行了分类,并对结果进行了细微的修改。然后由领域专家和一名研究人员对每个类别中的评论进行分类;在这个过程中,类别描述被进一步细化,要么聚合为主导描述符,要么分解为互补描述符。例如,“需要增加工程学位的广度和深度”被分解为(1)知识库的广度,(2)学习/真实性的深度,以及(3)改变课程以适应特定评论的解释重点/意图。两位主要研究人员对细化过程进行了交叉检查和关联。然后对类别进行统计,以显示前六个主题,并在活动2中重复此过程。对于活动3,根据CDIO教学大纲(Crawley,2001)对所需研究生能力的反应进行了映射,因为第20届澳大拉西亚工程教育协会会议阿德莱德大学,2009年12月6日至9日,ISBN 1 876346 59 0©2009 AAEE 2009 294分类法提供了高达4个级别的日益增加的特异性,从而允许转录的评论的更准确的表示。然后对由此产生的能力进行统计,得出前六名。结果和分析如表1所示,从转录本中鉴定出大量类别(共24个)。表1确定的类别总数社会意识公众认知知识库广度专业化实践经验设计环境意识全球化技术影响的快速变化工程系统规模或范围工程问题专业性研究/教学困境改变学生人口流动性和可转移性技能/资格终身学习深度/真实性参与度改变工程定义改变工程问题焦点改变学术人口结构改变课程通向工程沟通活动1问参与者:环境中的哪些新兴趋势对工程师和工程组织的影响越来越大?表2显示了六大新兴趋势。表2活动1:新兴趋势-前6类在活动2中,参与者被问到:你(和你的组织)如何应对在这种新兴环境中生存和发展的压力?工程教育工作者是如何适应的?大学是如何适应的?提出这个问题是为了促使参与者(个人或组织)反思在应对外部环境带来的机遇或威胁时存在的优势/战略和/或弱点/差距。以这种方式提出这个问题是为了期望在随后的活动中发现员工和未来毕业生的能力差距。表3显示了排名前六的回复。
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来源期刊
Ecological Restoration
Ecological Restoration Environmental Science-Nature and Landscape Conservation
CiteScore
1.70
自引率
12.50%
发文量
24
期刊介绍: Ecological Restoration is a forum for people advancing the science and practice of restoration ecology. It features the technical and biological aspects of restoring landscapes, as well as collaborations between restorationists and the design professions, land-use policy, the role of education, and more. This quarterly publication includes peer-reviewed science articles, perspectives and notes, book reviews, abstracts of restoration ecology progress published elsewhere, and announcements of scientific and professional meetings.
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